Structural Basis of the Migfilin-Filamin Interaction and Competition with Integrin β Tails

Lad, Yatish; Jiang, Pengju; Ruskamo, Salla; Harburger, David S.; Ylänne, Jari; Campbell, Iain D.; Calderwood, David A.

doi:10.1074/jbc.m802592200

Cited by 100 publications

(155 citation statements)

References 37 publications

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“…Lys-7, Arg-8, and Ser-11) are part of the binding surface for filamin repeat 21 (IgFLN21). The migfilin binding surface in IgFLN21 overlaps with the integrin binding surface (35,36). Thus, the binding of migfilin to Src SH2 domain could potentially be regulated by the interaction between migfilin and filamin, which in turn can be regulated by the interaction between integrins and filamin.…”

Section: Discussionmentioning

confidence: 99%

“…Our studies suggest that the reduction of the migfilin level induced by loss of cell-ECM adhesion is likely mediated by proteasomes. In this regard it is worth noting that unbound migfilin N-terminal region is unstructured (35,36). The binding of migfilin to Src SH2 domain or actin filament-associated proteins such as filamin may help to stabilize the structure of migfilin N-terminal region and thereby prevent proteasome-mediated degradation of migfilin.…”

Section: Discussionmentioning

confidence: 99%

“…The C-terminal region is composed of three LIM domains that mediate the interaction with kindlin-2/Mig-2 (27). Migfilin N-terminal region, which does not have obvious sequence homology with any other known proteins, possesses a binding site for filamin (27,35,36). In between the N-terminal region and the C-terminal LIM region lies a proline-rich domain that contains multiple proline-rich sequences.…”

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confidence: 99%

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Migfilin Interacts with Src and Contributes to Cell-Matrix Adhesion-mediated Survival Signaling

Zhao

Zhang

Ithychanda

et al. 2009

Journal of Biological Chemistry

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Integrin-mediated cell-extracellular matrix (ECM) adhesion is essential for protection of epithelial cells against apoptosis, but the underlying mechanism is incompletely understood. Here we show that migfilin, an integrin-proximal adaptor protein, interacts with Src and contributes to cell-ECM-mediated survival signaling. Loss of cell-ECM adhesion markedly reduces the migfilin level in untransformed epithelial cells and concomitantly induces apoptosis. Overexpression of migfilin substantially desensitizes cell detachment-induced apoptosis. Conversely, depletion of migfilin promotes apoptosis despite the presence of cell-ECM adhesion. At the molecular level migfilin directly interacts with Src, and the migfilin binding surface overlaps with the inhibitory intramolecular interaction sites in Src. Consequently, the binding of migfilin activates Src, resulting in suppression of apoptosis. Our results reveal a novel mechanism by which cell-ECM adhesion regulates Src activation and survival signaling. This migfilin-mediated signaling pathway is dysfunctional in multiple types of carcinoma cells, which likely contributes to aberrant Src activation and anoikis resistance in the cancerous cells.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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Migfilin Interacts with Src and Contributes to Cell-Matrix Adhesion-mediated Survival Signaling

Zhao

Zhang

Ithychanda

et al. 2009

Journal of Biological Chemistry

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“…1A) (7,8). A flexible hinge region (H1) between domains 15 and 16 divides the chain of 24 Ig-like domains into rod 1 (FLN (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)) and rod 2 (FLN(16 -24)) ( Fig. 1A) (9).…”

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confidence: 99%

“…This includes the first ␤-strand of FLNa (20) (Fig. 1B) that masks the integrin and migfilin binding site at the CD face of FLNa (21) (11,(13)(14)(15)(16) (Fig. 1B).…”

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confidence: 99%

Assembly of a Filamin Four-domain Fragment and the Influence of Splicing Variant-1 on the Structure

Pentikäinen

Jiang

Takala

et al. 2011

Journal of Biological Chemistry

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Filamins are large actin-binding proteins that stabilize threedimensional F-actin networks and link them to the cell membrane by binding to transmembrane receptors, e.g. integrins or ion channels. In addition, filamins bind to various other proteins with diverse function, including signaling and adaptor proteins, such as migfilin (1-6). Accordingly, filamins are considered as scaffolding proteins that integrate multiple cellular functions. Filamins are also associated with various human genetic diseases including malformations of the skeleton, brain, and heart (5).The filamin family has three members; filamins (FLNs) 4 A, B and C. The FLN genes are highly conserved, and the encoded proteins share about 70% overall sequence identity (6). FLNA is located on the X chromosome, whereas FLNB and FLNC are on autosomal chromosomes 3 and 7 (6). All three FLN genes are widely expressed during development, but in adults the most abundant isoform is FLNA. FLNC expression is predominantly restricted to skeletal and cardiac muscle cells (3). FLN proteins are homodimers of two 280-kDa polypeptide chains consisting of an N-terminal actin binding domain followed by 24 immunoglobulin (Ig)-like domains (FLN(1-24)) (6). The last domain, FLN(24), mediates dimerization (Fig. 1A) (7,8). A flexible hinge region (H1) between domains 15 and 16 divides the chain of 24 Ig-like domains into rod 1 (FLN(1-15)) and rod 2 (FLN(16 -24)) (Fig. 1A) Fig. 1) (10, 11). A similar intertwined interaction is, however, not seen with the domain pair FLNa(16 -17) (10).The diversity of the filamin family is increased by alternative splicing of FLN mRNA. These changes in amino acid sequence can affect the binding of other interacting partners. FLNa and FLNb splice variants (var-1), which are widely expressed at low levels, lack 41 amino acids including the C-terminal part of FLNa(19) and the N-terminal part of FLNa(20) (residues 2127-2167) (6,12). This includes the first ␤-strand of FLNa (20) (Fig. 1B) that masks the integrin and migfilin binding site at the CD face of FLNa(21) (11,(13)(14)(15)(16) (Fig. 1B). FLN var-1 binding to various integrins is increased compared with nonspliced filamins (11, 12), implying that alternative splicing could be a possible regulatory mechanism for binding to integrin and other interaction partners. Other possible mechanisms include mechanical force-induced exposure of the cryptic binding site on the CD face (17, 18) and/or the binding of other binding partners.Other splice variants are also found in FLNb and FLNc. The hinge region H1, which is responsible for the flexibility of FLN dimers, is missing in some FLNb and FLNc splice variants (12). Its absence might therefore affect the orthogonal cross-linking patterns made by FLN. The expression of different FLN splice variants appears to differ according to tissue type. The predominant isoforms in thyroid are FLNb containing H1 and FLNc lacking H1 (⌬H1) (19,20

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Supervillin binds the Rac/Rho‐GEF Trio and increases Trio‐mediated Rac1 activation

2015

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We investigated cross-talk between the membrane-associated, myosin II-regulatory protein supervillin and the actin-regulatory small GTPases Rac1, RhoA, and Cdc42. Supervillin knockdown reduced Rac1-GTP loading, but not the GTP loading of RhoA or Cdc42, in HeLa cells with normal levels of the Rac1-activating protein Trio. No reduction in Rac1-GTP loading was observed when supervillin levels were reduced in Trio-depleted cells. Conversely, overexpression of supervillin isoform 1 (SV1) or, especially, isoform 4 (SV4) increased Rac1 activation. Inhibition of the Trio-mediated Rac1 guanine nucleotide exchange (GEF) activity with ITX3 partially blocked the SV4-mediated increase in Rac1-GTP. Both SV4 and SV1 co-localized with Trio at or near the plasma membrane in ruffles and cell surface projections. Two sequences within supervillin bound directly to Trio spectrin repeats 4–7: SV1-171, which contains N-terminal residues found in both SV1 and SV4 and the SV4-specific differentially spliced coding exons 3, 4, and 5 within SV4 (SV4-E345; SV4 amino acids 276 – 669). In addition, SV4-E345 interacted with the homologous sequence in rat kalirin (repeats 4–7, amino acids 531 – 1101). Overexpressed SV1-174 and SV4-E345 affected Rac1-GTP loading, but only in cells with endogenous levels of Trio. Trio residues 771 – 1057, which contain both supervillin-interaction sites, exerted a dominant-negative effect on cell spreading. Supervillin and Trio knockdowns, separately or together, inhibited cell spreading, suggesting that supervillin regulates the Rac1 guanine nucleotide exchange activity of Trio, and potentially also kalirin, during cell spreading and lamellipodia extension.

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Structural Basis of the Migfilin-Filamin Interaction and Competition with Integrin β Tails

Cited by 100 publications

References 37 publications

Migfilin Interacts with Src and Contributes to Cell-Matrix Adhesion-mediated Survival Signaling

Migfilin Interacts with Src and Contributes to Cell-Matrix Adhesion-mediated Survival Signaling

Assembly of a Filamin Four-domain Fragment and the Influence of Splicing Variant-1 on the Structure

Supervillin binds the Rac/Rho‐GEF Trio and increases Trio‐mediated Rac1 activation

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